FI74876C - Wiring diagram for a magnetotherapy pulse device. - Google Patents

Abstract

Circuit arrangement of magnetotherapeutic impulse device for treatment of inflammatory and degenerative illnesses such as spondylitis, e.g. Bechterew's disease, operating on the principle of a pulsatory magnetic field, the frequency and intensity of which can be adjusted within an wide range, enabling the operator the adjustment and control of treatments for a number of different treated sites.

Description

74876

Wiring diagram for a magnetic therapy pulse device

The invention relates to a circuit diagram of a magnetic therapeutic pulse device comprising a plurality of electromagnetic coils 5 connected in series with corresponding power supply units and a voltage source, means for adjusting the excitation frequency of the electromagnetic windings to a multiplexed excitation frequency, and means for adjusting the excitation energy The wake-up energies are adjustable. Such an impulse device is particularly suitable for the treatment of inflammatory and congenital diseases.

Such magnetic therapeutic pulse devices are based either on the discharge of a capacitor in an electric-15 magnet winding or on the connection of an electromagnetic winding to a multivibrator circuit, a thyristor winding circuit with switch.

The disadvantages of the devices are mainly the inability to adjust the power supplied to the windings, the periodic oscillation of the magnetic field cannot be precisely controlled, and no solution is known as to how it would be possible to change the frequency of the periodic oscillation under automatic control. In all devices, it is possible to connect a small number, up to four windings, to the circuit. Only some solutions guarantee synchronization with the phase of the applied voltage when closing the winding current and thus the uniformity of the heart rate of the magnetic field. Most of the known solutions use mechanical switches, which increase the size and reduce their reliability.

It is an object of the present invention to eliminate or at least reduce these disadvantages.

74876 This object is achieved by a circuit diagram of an impulse device according to the invention, characterized in that the output of a circuit connected to a voltage source is connected to the inputs of synchronization units, the outputs of which are connected to the inputs of 10 power connection units, that the outputs of the electronic changeover switch are further connected from the second output to the inputs of the multipath switch.

Preferred embodiments of the invention are set out in claims 2-7.

An advantage of the arrangement according to the present invention is primarily the possibility to adjust the power to the individual electromagnetic coils and to continuously, automatically and manually control the change of the periodic oscillation frequency in the generated magnetic field, thus ensuring accurate magnetic field application in medical use of the system. The possibility of the Joh-25 support to simultaneously connect a large number of electromagnetic coils offers the possibility to use a magnetic field on a large number of objects to be treated, for example the whole back or the like. Due to said connection, synchronization between the power connection and the phase of the voltage supplied by the voltage source 30 is guaranteed, which ensures the uniformity of the pulse of the magnetic field in the field generated by the electromagnetic windings. By using electronic elements for non-contact connection and digital control, high reliability in the operation of the described system and low power consumption are achieved.

74876 The circuit of a magnetic therapeutic impulse device according to the present invention will now be described by way of example with reference to the drawings, in which Figure 1 shows a block diagram of the basic connection of a magnetic therapy pulse device, Figure 2 shows connection example.

10 According to Fig. 1, which shows the basic connection of a magnetic therapy pulse device, the voltage control circuit 2 connected to the voltage source 1 is connected to its output both to the timing input in the electronic the outputs are connected to control outputs in power connection units 11a to 1, which are connected in series with electromagnetic windings 12a-12e and connected to a voltage source 120 and from another output to the output of a multipath switch 5, the output connected to zero input in electronic changeover switch 4.

25 In order to increase the power, the basic circuit of the magnetotherapeutic pulse device has been supplemented with the following circuits as shown in Fig. 2. The unit 7 indicating the adjusted oscillation frequency is connected to the output in the control unit 6 of the multipath switch 5.

The timing switch 3 is connected between the output of the voltage control circuit 2 and the timing input of the electronic switch 4 and the control unit 6 of the multipath switch.

Circuits 9a-9e, which indicate switching, are connected in parallel to the inputs 35 of the synchronization units 8a-8e.

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The isolation units 10a-10e are connected to the control input of the power connection units 11a to 11 and between the outputs of the synchronization units 8a to 8e.

The detection circuits 13a-13e are connected in parallel to the electromagnetic coils 12a-12e.

A simple five-pole changeover switch 14 is connected to the storage unit circuit 15 by opposite terminals in parallel with the electromagnetic windings 12a-12e.

When the circuit 10 of the magnetotherapeutic pulse device operates, the voltage control circuit 2 connected to the voltage source 1 adjusts the input sinusoidal voltage to the required magnitude and converts the voltage into a claw shape.

The voltage thus regulated is applied both to the timing input in the electronic changeover switch 4 and to the timing si-15 control input in the multipath switch control unit 6. The individual outputs of the electronic changeover switch 4 have successive transitions from one logic level to another. 4 the outputs 0-n are connected to the inputs of the synchronizing units 8a-8e, thereby creating a time delay in their output signals with respect to the input signals and at the same time a phase shift between closing the power connection units 11a and the phase 12 series connection between the power connection units 11a-11a and the voltage source 1, makes it possible to adjust the power to the individual electromagnetic windings 12a-12e. In addition, from the second output, the outputs of the electronic changeover switch 4 are connected to the inputs O-n of the multipath switch 5, the outputs of which are connected to the zero input of the electronic changeover switch 4. The control of the multipath switch 5 is provided by means of the multipath switch control unit 6. This multipath switch control unit 6, 35, which is connected via its timing input to the voltage control circuit 2 and via its output to the multipath switch 5

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74876, causes the logic planes to shift from the outputs of the electronic changeover switch 4 to the zero input in the electronic changeover switch 4 and thus, depending on the control of the multipath switch control unit 6, allow the The equilibrium of the magnetic field generated by the -12e with the voltage supplied from the voltage source 1 further ensures 10 the possibility to adjust the power in the individual electromagnetic windings 12a-12e by means of in the electronic changeover switch 4 and thus provide the possibility to change the periodic oscillation frequency generated by the electromagnets of the electromagnetic windings 12a-12e field.

The circuits connected to the basic switching system, as shown in Figure 2, provide the following confirmation of operation.

Access to the controlled cycle number is ensured by connecting the controlled cycle number detection unit 7 to the output of the multipath switch control unit 6. To adjust the time during which the patient is in the treatment treatment, a timer switch 3 is set between the outputs of the voltage control circuit 2 and the timing inputs of the electronic changeover switch 4 and the multipath switch control unit 6.

Access to information on the operation of the logic part of the device is ensured by connecting the changeover detection circuit 9a-9e in parallel to the inputs of the synchronization units 8a-8e.

The separation of the logic parts of the device from the power parts takes place by placing the separating units 10a-10e on the power connection units 11a between the control inputs and the outputs of the synchronizing units 8a-8e.

Access to information about the excited magnetic field and at the same time about the possible skew of the power connection units 11a to 1 is ensured by connecting the detection units 13a-13e in parallel to the electromagnetic windings 12a-12e.

74876

Access to information on the shape and magnitude of the voltage in the individual electromagnetic windings 12a-12e is ensured by connecting a simple n-pole changeover switch 14 in parallel to the electromagnetic windings 12a-12e and connecting its opposite connectors to the storage unit circuit 15.

A practical example of the connection of a magnetotherapeutic pulse device, in accordance with the present invention, is seen in combination in Figures 3a and 3b. The mains voltage from the source 1 10 is supplied to the input of the voltage control circuit 2, which includes a main transformer, the secondary winding of which is energized by the DC voltage converter 2a and supplied to the low-current parts of the device. The voltage draw to the pulse shaper 2b to convert the sinusoidal voltage to the square shape is also taken from the secondary winding.

15 The voltage thus regulated is applied to the input of the timing switch 3, and through this at a predetermined time it passes to the output and from there to the timing input in the electronic changeover switch 4 and the timing input in the multipath switch control unit 6. The electronic changeover switch 4 20 includes a counter 41 and a converter 42 inputs are connected to the BCD outputs of the loop 41. The input timing frequency is converted in the calculator 41 into a BCD code, and the converter 42 1 ^ -n switches its outputs from one logic level to another, in step with the entered timing period number. The outputs of the electronic changeover switch 4 are connected to the inputs of the synchronization units 8a-8e, to which the inputs in the changeover detection circuits 9a-9e are connected in parallel, indicating, for example, the optically prevailing logic levels at the outputs of the electronic changeover switch 4. The synchronization units 30a-8e take care of the phase shift of the signal at their outputs with respect to the phase of the signal at their inputs and thus also with respect to the phase of the alternating voltage supplied from the voltage source 1. The outputs of the synchronization units 8a-8e are connected to the inputs in the isolation units 10a-10e, the outputs 35 of which are connected to the control inputs in the power connection units 11a to 1. The separation units 10a-10e secure the passage of the signals.

74876 from the synchronization units 8a-8e to the control inputs in the power connection units 11a to 1 and electrically separate the control electronics from the power part of the system. By applying a signal to the control inputs of the power connection units 11a to 1, these units enter a conductive state and due to their series connection with the electromagnetic windings 12a-12e and the voltage source 1, an electric current flows in the circuit generating a magnetic field. The detection circuits 13a-13e connected in parallel to the windings 12a-12e optically flash the generation of a magnetic field by the flash 10 and at the same time act as a detector in the event of a fault in the power connection units 11a, so that they burn continuously when the current flows continuously and thus with a variable magnetic field. . Depending on the position of the single-15 fold n-pole toggle switch 14 when connected to the solenoid coils 12a-12e and its opposite terminals to the storage unit circuit 15, caregivers receive information about the amplitude and shape of the voltage pulse in the private solenoid coils 12a-12e. The driving frequency, which is fed from the output of the timing device 3 to the timing input and from there the claw-shaped voltage at period numbers 1 ", 10", 30 ", 1 ', 2', 5 'and 10' is taken out through its separate outputs and fed to the terminals in a simple, multi-pole changeover switch 62 A simple multipole changeover switch 62a supplies voltage at a selected period to the first inputs at the positive dual ports 63 and 64, the second inputs of which are connected to a control circuit 65a 30 with their outputs Q and Q. The outputs of the positive dual ports 63 and 64 are connected. to the inputs Cp and Cp of the reversing counter 66. The switching circuit of the control circuit 65a is performed by a switching switch 62b which ensures in both extreme positions that the outputs Q and Q of the control circuit 65a become either logical levels L and H or H and L, and thus the signal is transmitted through a positive double port 63 and 64 8 74876 to the input CD or Cy of the reversible counter 66, whereby the forward or backward counting is performed reliably. With the changeover switch 62b in the center position, the automatic changeover of the outputs Q and 0 of the control circuit 65a from the converter 67 by means of the outputs 0 and 9 connected to the center terminals of the changeover switch 62b. The BCD input of the converter 67 _l-n is connected to the BCD output of the reversing calculator 66, whereby the shift will flick forward and the entire cycle will be repeated continuously. In addition, the BCD outputs of the reversible counter 66 are connected to the inputs 15 to 15 in the memory 68. The toggle switch 62a and the memory lock circuit 65 make it possible to prevent the binary coded number from flowing from the input to the output and thus maintain the selected number at the output of the memory 68 regardless of the current state at the BCD output of the reversing counter 66. The outputs 20-20 of the memory 68 are connected both to the inputs in the adjustable period number detection unit 7 and to the BCD inputs of the multipath switch.

The outputs of the electronic changeover switch 4 are connected from the second output to the input 25 of the multipath switch 5. The output of the multipath switch 5 is connected to the zero input in the electronic changeover switch 4. The operation of the multipath switch 5 thus connected is that logic levels are transferred from the output of the electronic changeover switch 4 to the multipath switch output only from the output Thus, the logic level H from its output to the zero input in the electronic changeover switch 4 or 41, respectively, is eliminated, indicating the return of the connection in the electronic changeover switch 5 to the output O. Depending on the input transferred by the multipath 35 switch 5, the counting period 7 is shortened or extended. through the converter 42 1 ^ -n, the power connection units 11a-11e of the synchronization elements 8a-8e, the separation units 10a-10e and the control inputs, an increase or decrease of the periodic oscillation frequency in the magnetic field generated by the electromagnetic windings 12a-12e 5 occurs. The adjusted period number detecting unit 7 detects the root-adjusted periodic oscillation frequency in the excited magnetic field.

The switching system of the magnetotherapeutic pulse device guarantees the possibility to select the division oscillation frequency of the magnetic field, which is determined by dividing by an integer, but at least 2: 11a, the period of the voltage given by the voltage source 1. It is possible to select one cycle number by closing the memory 68 with the toggle switch 62a through the memory lock circuit 65b. In addition, based on the control of the changeover switches 62a, 62b, it is possible to select, in the periods determined by the distribution block 81, an automatic increase or decrease of the periodic oscillation frequency in the excited magnetic field or an automatic increase and a subsequent decrease or vice versa. By adjusting the synchronization units 8a-8e, it is possible to provide a phase shift between the closing of the power supply devices and the phase of the voltage supplied from the voltage source 1 and thus adjust the power supplied to the individual electromagnetic windings 12a-12e. By adjusting the timer switch 3, a complete stop in the device is achieved after a predetermined time 25. The adjusted period number detection circuit 7 informs the periodic frequency of the excited magnetic field. The changeover field detection circuits 9a-9e convey information about the correct operation of the electronic changeover switch 4. The detection circuits 13a-13e indicate the existence of an excited magnetic field. By means of a simple n-pole changeover switch 14 and a storage unit circuit 15, it is possible to check the magnitude and shape of the voltage pulses in the electromagnetic windings 12a-12e.

Claims (7)

1. Wiring diagram of a magnetotherapeutic pulse device, comprising several electromagnetic coils (12a-12e), which are connected in series with the corresponding power connection units (11a) and a voltage source (1), means (4,5,6). for controlling the magnetization frequency of the electromagnet coils, and means (8a-8e) for controlling the magnetization energy supplied to the electromagnet coils, the magnetization frequency and the magnetization energy supplied in one or more of the electromagnet coils being adjustable, characterized in that circuit (2) connected to the voltage source (1) and intended to regulate the voltage 15 and change the sine path from the voltage source in a rectangular form is coupled to the input of the timing in an electronic switch (4) and in the input of the timing in a control unit (6) of a multipath switch (5), that the outputs (0-n) of the electronic switch (4) are coupled to the inputs of synchronization units (8a-8e), which outputs the wires are connected to the inputs of the power connection units (11a), that the outputs of the electronic switch (4) are further connected even from their other outputs to the inputs (0-n) of the control unit of the multi-way switch (5) 6) is coupled to the control input of the multipath switch (5), and the output of the multipath switch is connected to the zero input of the electronic switch (4). 2. A circuit diagram according to claim 1, characterized in that a display device (7) for a controllable period number is connected to the output of the control unit of the multipath switch (6). Wiring diagram according to claim 1 or 2, characterized in that a timing coupling (3) is connected between the output of the voltage II